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Mar 31, 2016 - Graphene Oxide Nanosheets Reshape Synaptic Function in Cultured Brain Networks. Rossana Rauti†, Neus Lozano‡, Veronica León§, Den...
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Graphene oxide nanosheets reshape synaptic function in cultured brain networks Rossana Rauti, Neus Lozano, Verónica León, Denis Scaini, Mattia Musto, Ilaria Rago, Francesco Paolo Ulloa Severino, Alessandra Fabbro, Loredana Casalis, Ester Vázquez, Kostas Kostarelos, Maurizio Prato, and Laura Ballerini ACS Nano, Just Accepted Manuscript • DOI: 10.1021/acsnano.6b00130 • Publication Date (Web): 31 Mar 2016 Downloaded from http://pubs.acs.org on April 1, 2016

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Graphene Oxide Nanosheets Reshape Synaptic Function in Cultured Brain Networks

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Rossana Rauti†, Neus Lozano§, Veronica León ‡, Denis Scaini†,#, Mattia Musto ø, Ilaria Rago#, Francesco P. Ulloa Severino ø , Alessandra Fabbro║, Loredana Casalis#, Ester Vázquez‡, Kostas Kostarelos§, Maurizio Prato║&¥* and Laura Ballerini†,ø*

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Life Science Department, University of Trieste, 34127 Trieste, Italy Nanomedicine Lab, School of Medicine and National Graphene Institute, Faculty of Medical & Human Sciences, University of Manchester, M13 9PL Manchester, United Kingdom ‡ Departamento de Química Orgánica, Facultad de Ciencias y Tecnologías Químicas-IRICA Universidad de Castilla La-Mancha, 13071 Ciudad Real, Spain # ELETTRA Synchrotron Light Source, 34149 Trieste, Italy ø International School for Advanced Studies (SISSA), 34136 Trieste, Italy ║ Department of Chemical and Pharmaceutical Sciences, University of Trieste, 34127 Trieste, Italy & CIC BiomaGUNE, Parque Tecnológico de San Sebastián, Paseo Miramón, 182, 20009 San §

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Sebastián (Guipúzcoa), Spain

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¥

Basque Foundation for Science, Ikerbasque, Bilbao 48013, Spain

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* Corresponding authors: Laura Ballerini International School for Advanced Studies (SISSA)

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via Bonomea 265 I-34136 Trieste [email protected] ; [email protected]

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Abstract

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Graphene offers promising advantages for biomedical applications. However, adoption of

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graphene technology in biomedicine also poses important challenges in terms of understanding

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cell responses, cellular uptake or the intracellular fate of soluble graphene derivatives. In the

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biological microenvironment graphene nanosheets might interact with exposed cellular and

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subcellular structures resulting in unexpected regulation of sophisticated biological signaling.

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More broadly, biomedical devices based on the design of these 2D planar nanostructures for

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interventions in the central nervous system (CNS) requires an accurate understanding of their

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interactions with the neuronal milieu. Here, we describe the ability of graphene oxide

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nanosheets to down-regulate neuronal signaling without affecting cell viability.

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Keywords

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Nanotechnology; graphene; patch-clamp; synaptic terminals; exocytosis; FMI-43;

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microvesicles.

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Graphene is a 2D plate-like material consisting of sp2-hybridized carbon atoms

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organized in a hexagonal lattice and characterized by, among other properties, high electron

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mobility and mechanical flexibility.1-3 In addition to the successful exploitation of graphene and

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graphene-based materials in an increasing number of industrial products, current applications of

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graphene hold the potential to revolutionize specific areas of medicine.2-6 Biomedical

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developments in general, in neurology in particular, are focusing on few-layer graphene sheets

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to manufacture novel bio-devices, including biosensors, interfaces, tissue scaffolds, drug

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delivery and gene therapy vector systems.4 The successful design of multifunctional graphene-

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based neuro-devices will expose brain cells and neuronal circuits directly to this material by

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injection or implantation.4,7 In this context, the exploration of the interactions between graphene

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nano- and micro-sheets with the sophisticated signaling machinery of nerve cells, with a

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particular focus on potential graphene flake interactions with the hydrophobic membrane

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domains, is of great importance.1,8,9 Such interactions may favor graphene translocation, or

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adhesion to cell membranes,8,10 potentially interfering with exquisite membrane activities, such

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as the exocytic and endocytic trafficking systems, crucial to physiological synaptic

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transmission.8,11

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Here we explore by patch clamp and fluorescence imaging the ability of graphene (GR)

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and graphene oxide (GO) nanosheets to interfere with synaptic signaling once hippocampal

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cultured neurons are exposed for one week to a growth medium containing thin sheets of such

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materials at 1 or 10 µg/mL (concentrations reported not to induce cell death12-14). We further

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investigated whether, in the absence of explicit cell toxicity, such materials affected the ability

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of astrocytes to release synaptic-like microvesicles15 (MV) in pure glial cultures. Our results

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describe the potential of GO nanosheets to alter different modes of inter-neuronal

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communication systems in the CNS hinting at opportunities for neuromodulatory applications

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or highlighting subtle, but potentially unwanted, subcellular interactions.

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Results/Discussion To address the issue of prolonged exposure of a functional brain network to graphene

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sheets we used different materials. Graphene oxide sheets of large and small lateral dimensions

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(l-GO and s-GO, respectively) were synthesized using a modified-Hummers method (see

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Methods). Following the reaction, the GO-gel like upper layer was extracted carefully by using

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warm water, resulting in the large GO (l-GO). Final concentrations ranged between 1 and 2

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mg/mL were obtained with a yield of ca. 10%. l-GO was freeze-dried, reconstituted in water for

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injection, sonicated for 5 mins and centrifuged at room temperature to generate the small GO (s-

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GO).The lateral dimension of GO sheets was controlled by drying and sonicating the l-GO to

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obtain the s-GO sheets, that were always at least one order of magnitude smaller, without

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introducing any significant changes among their surface properties (see Table S1 in the

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Supporting Information).

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The GO dispersions in aqueous media were homogenous, of brownish color and stable at

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room temperature for more than 6 months. The physicochemical characterization of the l-GO and

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s-GO dispersions is shown in Figure 1 (a-f), and in the Supporting Information Figure S1 and S2.

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The structural properties (lateral dimension and thickness) were studied by optical microscopy,

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transmission electron microscopy (TEM) and atomic force microscopy (AFM). Optical

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properties were studied by UV-Vis and fluorescence spectroscopy. Raman spectroscopy and

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laser Doppler electrophoresis (measuring ζ–potential) were used to assess the surface properties

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of the GO materials. The Raman spectroscopic analysis revealed D and G bands at 1319 cm-1

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and 1596 cm-1, respectively, characteristic of most poly-aromatic hydrocarbons. The D to G band

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intensity ratio (ID/IG) was calculated at 1.3, corresponding to the metric of disorder in the

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graphitic structure. The surface charge measured with a Zetasizer instrument showed an average

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ζ–potential of -50 mV, indicating flakes of high negative surface charge. To elucidate the degree

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of surface functionalization, thermo-gravimetric analysis (TGA) and X-ray photoelectron

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spectroscopy (XPS) survey spectra were performed to quantify the purity of the GO (> 99%) and

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the C:O ratio. XPS high resolution C1s spectra were recorded to elucidate the contribution of

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individual functional groups such as carboxylic, carbonyl, epoxide and hydroxyl (Table S2b). All

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fittings shown were performed using the CasaXPS software and the different regions were

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assigned according to Nist XPs and lasurface databases. Deconvolution XPS spectra and

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assignment of the functional groups indicated that hydroxyls were the least abundant species in

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the GO material (see also Supporting Information, Table S2a).

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Aqueous dispersions of graphene (GR) flakes were prepared using ball-milling for the

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exfoliation of graphite through interaction with melamine, as previously described16,17 (see

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Methods). Due to the GR preparation process, graphene dispersions can contain traces of

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melamine. In order to determine the exact amount of these traces, final graphene dispersions

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(0.09 mg/mL) were evaluated by elemental analysis, which indicated 0.9 ppm of melamine.

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Experiments that involved incubation in neurons also included controls exposed to equal

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amounts of melamine alone (see Methods). The physicochemical characterization of GR

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dispersions is shown in Figure S3. The lateral size, studied by TEM, was found to range between

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500nm-3µm (Figure S3a-b in the Supporting Information). Optical properties were studied by

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UV-Vis absorption spectroscopy. Dispersions were diluted and the respective UV-Vis absorption

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spectra were recorded (Figure S3). The spectra are featureless in the Vis–NIR region, as

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expected. The absorbance at 660 nm, divided by cell length, is plotted against the concentration

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exhibiting Lambert-Beer behavior (Figure S3d). Raman spectroscopy revealed differences

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between the GO and GR. Graphene exhibits G and 2D modes around 1573 and 2700 cm-1, that

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satisfy Raman selection rules, while the D peak, around 1345 cm-1 requires a defect for its

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activation (Figure S3e). The D to G band intensity ratio was calculated at different locations,

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giving a significant low value (0.22) in comparison with GO. TGA was also used to quantify the

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functionalization degree of GR. The low weight loss observed in GR (7%) corroborated the low

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quantity of oxygen groups generated by the exfoliation process (Figure S3f).

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We used hippocampal neurons isolated and cultured for 8-10 days in vitro (DIV).

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Primary neuronal cultures were incubated for 2 DIV in the presence of GR or s-GO (at 1 µg/mL

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and 10 µg/mL; see Methods) and maintained for 6 to 8 days. Afterwards visually identified

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neurons were patch clamped under voltage clamp. Hippocampal neuron maturation and viability

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were assessed using single-cell recordings (see Methods) to measure the cell passive membrane

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properties that are accepted indicators of neuronal health18-20 that allowed comparison among the

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recorded cells. These parameters (membrane capacitance and input resistance) displayed similar

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values in all treatment conditions (summarized in Table 1).

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Table 1. Neuronal passive membrane properties upon GR and s-GO exposure (1 µg/mL and 10 µg/mL respectively). Capacitance (pF)

Input Resistance (MΩ)

Control1

n=24

59 ± 4

976 ± 138

Melamine1

n=28

46 ± 5

1036 ± 132

62 ± 8

876 ± 145

50 ± 5

1029 ± 161

57 ± 7

744 ± 82

72 ± 16

717 ± 106

67 ± 6

997 ± 156

59 ± 18

1223 ± 501

s-GO1 GR1

n= 27 n=30

Control10

n=20

Melamine10 s-GO10 GR10

n=25

n=18 n=25

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To investigate synapse formation and activity after in vitro growth of neurons, we

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monitored the occurrence of spontaneous postsynaptic currents (PSCs). The appearance of PSCs

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provided clear evidence of functional synapse formation and it is a widely accepted index of

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network efficacy.21,22

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Figure 1g, shows representative current tracings of the recorded electrical activity. In

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neurons exposed to low (1 µg/mL) s-GO and GR, spontaneous synaptic activity was not

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affected. In fact, measured PSC amplitude and frequency in s-GO and GR (79 ± 7 pA and 2.5 ±

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0.4 Hz n=27 and 77 ± 8 pA and 3 ± 0.5 Hz, n= 30, respectively) were comparable to the

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corresponding control and control-melamine values (87 ± 8 pA and 2.3 ± 0.3 Hz, control, n=24;

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80 ± 15 pA and 2.3 ± 0.5 Hz melamine n= 28; plots in Figure 1 (g)). In all tests, cell parameters

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measured in melamine were comparable to those expressed by control neurons (Figure 1 (g)

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bottom plots), thus the impact on cells of such a contaminant at the estimated concentration is

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negligible.

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When investigating the impact of higher graphene doses (10 µg/mL) we detected a

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significant difference (P < 0.001; Student’s t-test) in PSC frequency when comparing control

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neurons (2.0 ± 0.1 Hz control, n= 20) with s-GO treated ones (0.6 ± 0.1 Hz, n= 18), while in

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melamine and GR, PSC frequency values remained unchanged (2.5 ± 0.7 Hz melamine, n= 25

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and 2.8 ± 1.1 Hz GR; n= 25). In all treatments studied, the amplitude values of the PSCs were

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never affected (data are summarized in Figure 1 (g) plots). We further tested synaptic responses

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when neurons were treated (1 and 10 µg/mL) with a commercially available GO provided by an

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industrial partner (A-GO; Supporting Information and Figures S4). Similar reduction in PSC

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frequency (Figure S5) was detected that validated the observation that GO nanosheets,

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differently to GR flakes, specifically interfered with synapses in cultured neurons, regardless of

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the starting material.

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The impact of 10 µg/mL s-GO on synaptic activity was not related to a decreased

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number of surviving neurons in the presence of s-GO. In fact, we determined the cellular

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composition of control and s-GO treated hippocampal cultures using immunofluorescence

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markers23 for astrocytes (GFAP) and neurons (β-tubulin III). We observed both β-tubulin III and

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GFAP immunoreactive cells in all growing conditions (Figure 2 (a)) and both cell groups were

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represented in a comparable proportion in all treatment groups (quantified by measuring the cell

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density in Figure 2 (a), (n=13 visual field per condition, 3 different culture series). Thus s-GO at

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higher concentrations specifically altered synapse formation and/or function without affecting

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cell survival or the global network size.

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To gain more insight into such processes we further investigated s-GO-treated (10

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µg/mL) cultures. We specifically addressed the distribution of neuronal excitation by measuring

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the activity of small clusters of neurons with fluorescence calcium imaging.23-25 On average 7±2

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fluorescent neurons (n=26 fields), stained with the membrane permeable Ca2+ dye Fura-2-AM

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(see Methods), were simultaneously visualized in the recorded field (120 x 160 µm2). We

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compared and characterized the cell ability to generate repetitive Ca2+ oscillations.23-25 In control

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conditions all recorded fields (n=8) displayed active cells, while in s-GO treated cells 56%

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(n=10 out of 18) of the recorded fields did not display detectable cell activity. However, in the

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remaining s-GO fields (n=8), we found an amount of neurons that were spontaneously

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generating repetitive Ca2+ oscillations comparable to that measured in controls (Figure 2 (b),

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36% in control, 20 out of 56 neurons, n=8 active fields and 30% in s-GO-treated, 18 out of 60

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neurons, n=8 active fields).

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Figure 2 (b) traces represent fluorescence recordings from active fields in control and s-

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GO-treated cultures (2 sampled cells in each field). Episodes usually comprised spontaneous

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bursts of activity, fully blocked by tetrodotoxin (TTX, a blocker of voltage-gated, fast Na+

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channels) applications (1 µM; n= 8 fields, control and s-GO-treated; not shown). Control Ca2+

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oscillations displayed an inter-event interval (IEI) of 36 ± 2 s (n=20 cells) that was significantly

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lower (P < 0.001; Student’s t-test) than that measured in s-GO-treated networks (110 ± 6 s, n=18

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cells, right plot in Figure 2 (b)). When GABAA receptors were pharmacologically blocked by

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bicuculline (20 µM; 20 min), an antagonist of inhibitory connections known to potentiate

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rhythmic activity patterns,23,26,27 the control IEI average value was still significantly lower (P
510 nm were acquired continuously

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for a maximum of 2400 s (200 ms individual exposure time) by a cooled slow-scan interline

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transfer camera (IMAGO CCD camera; Till Photonics). The camera was operated on 8x8 pixel

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binning mode and the imaging system was controlled by an integrating imaging software

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package (TILLvisION; Till Photonics). To induce rhythmic bursts, 20 µM bicuculline

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methiodide was bath-applied after 15 min recording;23 at the end of each experiment,

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tetrodotoxin (TTX 1 µM; Latoxan) was applied to confirm the neuronal nature of the recorded

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signals.23 Recorded images were analyzed off-line by Clampfit software (pClamp suite, 10.2

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version; Molecular Devices LLC, US) and Igor Pro Software (6.32 A version; WaveMetrics,

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Lake Oswego, Oregon, USA). Intracellular Ca2+ transients were expressed as fractional

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amplitude increase (∆F/F0 where F0 is the baseline fluorescence level and ∆F is the rise over the

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baseline); elevations in calcium level were considered significant if they exceeded five times

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the standard deviation of the noise. We then computed the difference between consecutive onset

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times to obtain the inter-even interval (IEI). Hence, after obtaining the IEI values from each

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active cell in the field, data were pooled for all fields recorded under the same experimental

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conditions and averaged for further comparison.

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FM1-43 loading and de-staining

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Depolarization-dependent staining of synaptic terminals with the styryl dye N-(3-

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triethylammoniumpropyl)-4-(4-(dibutylamino)styryl)pyridinium dibromide (FM1-43,

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Molecular Probes, Life Technology) was obtaining by incubating cultures (after 10 min saline

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buffer wash at RT) for 120 s with 50 mM KCl and FM1-43 (15 µM). The buffer was replaced

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by 2 mL of normal saline containing FM1-43 and cells were left to recover for 10 min, to

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ensure complete recycling of the vesicles,63 and then incubated for 10 min with saline

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containing 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 10 µM) and 2-

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aminophosphonovaleric acid (2-APV; 50 µM) to prevent network activity altering the rate of

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FM release. These antagonists were present throughout the experiment. After incubation with

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FM1-43 dye, cultures were transferred to the stage of a Nikon Eclipse Ti-U inverted

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Microscope equipped with a piezoelectric table (Nano-ZI Series 500 µm range, Mad City

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Labs), HBO 103 W/2 mercury short lamp (Osram, Munich, Germany), mirror unit (exciter filter

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BP 465-495 nm, dichroic 505 nm, emission filter BP 515-555), and Electron Multiplier CCD

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Camera C9100-13 (Hamamatsu Photonics, Japan). Images were acquired with an oil-immersion

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Plan Apo 100x (1.4 NA, Nikon, Japan) objective at a sampling of 2 Hz with a spatial resolution

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of 256 x 256 pixels. All experiments were performed at RT. Application of 50 mM KCl (5 sec),

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followed by a 2 min washout was used to stimulate vesicles exocytosis from the dye-containing

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terminals, measured as a fluorescence loss. The imaging system was controlled by an

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integrating imaging software package (NIS Element, Nikon, Japan). Off-line analysis was

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performed on image sequence with the image-processing package Fiji.64 After background

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subtraction, images were analyzed using rounded ROIs of 4 pixels in diameter drawn on neural

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processes. Endocytosed vesicles during FM1-43 loading were measured by estimating the

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brightness of the total vesicle pool puncta (raw fluorescence intensity) in GO-treated and

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untreated cultures before the unloading stimulus. The decay time constant, τ was measured by

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pClamp 10.2 software (Molecular Devices LLC, US). To avoid imaging nonselective FM

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staining, only puncta that showed stimulus-dependent de-staining were included in the analyses.

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Immunofluorescence labeling

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Hippocampal neurons or glial cells, treated and untreated, were fixed in PBS containing 4%

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PFA for 20 min, at RT. Cells were permeabilized with 1% Triton X-100 for 30 min, blocked

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with 5% FBS in PBS for 30 min at RT and incubated with primary antibodies for 30 min. The

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primary antibodies used were: rabbit polyclonal anti-β-tubulin III (Sigma T2200, 1:250

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dilution), mouse monoclonal anti-GFAP (Sigma-Aldrich, 1:500 dilution) and guinea pig

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polyclonal anti-vesicular glutamate transporter (Millipore AB5905, dilution 1:2000). After the

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primary incubation and PBS washes, neurons were incubated for 30 min with the secondary

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antibodies AlexaFluor 594 goat anti rabbit (Invitrogen, dilution 1:500), AlexaFluor 488 goat

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anti mouse (Invitrogen, dilution 1:500), AlexaFluor 488 goat anti guinea pig (Invitrogen,

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dilution 1:500), and DAPI (Invitrogen, dilution 1:200) to stain the nuclei. Samples were

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mounted in Vectashield (Vector Laboratories) on coverslips of 1 mm thickness. Cell densities

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were quantified at 20x (0.5 NA) magnification using a DM6000 Leica microscope (Leica

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Microsystems GmbH, Wetzlar, Germany), with random sampling of seven to ten fields (713 x

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532 µm; control and treated, n=3 culture series). For VGLUT1-positive terminals, image

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acquisition was performed using a confocal microscope (Leica Microsystems GmbH, Wetzlar,

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Germany) 63x (1.4 NA) magnification (Z-stacks were acquired every 300 nm; 12 fields for

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control and untreated conditions). Offline analysis was performed using Volocity software

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(Volocity 3D Image Analysis Software, PerkinElmer, Massachusetts, USA). For each set of

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experiments, the images were acquired using identical exposure settings. The ROIs for the

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quantification were blindly chosen using the tubulin channel. For each analyzed field, we used

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the Z-stacks to quantify VGLUT1 puncta as 3D objects. The resulting numbers were

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normalized to the relative cellular volume calculated on the basis of β-tubulin III labeling.

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Micovesicles isolation and characterization

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Microvesicles (MVs) shedding was induced in 21 DIV confluent glial cells (after washing in

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PBS, 37 °C) upon exposure to Benzoyl-ATP (BzATP; 100 µM) in Krebs-Ringer solution with

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the following composition: 125 mM NaCl, 5 mM KCl, 1.2 mM MgSO4, 1.2 mM KH2PO4, 2

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mM CaCl2, 6 mM D-Glucose and 25 mM HEPES/NaOH (pH adjusted to 7.4), for 30 min at 37

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°C and 5% CO2.39 MVs were pelleted by centrifugation as described in Bianco et al. 2009.39

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Negative controls were incubated with Krebs-Ringer solution without the presence of BzATP.

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MVs isolated from confluent mixed glial cells were re-suspended in lysis buffer (50 mM Tris-

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HCl, pH 8.0, 150 mM NaCl, 1% NP40, 0.1% SDS), sonicated 3 x 10 s and then boiled at 95 °C

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for 5 minutes. Samples ran on a 10% polyacrylamide gel and were blotted onto nitrocellulose

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filters (Millipore, Italy). Filters were then blocked in PBS-Tween-20 (0.1%) plus 5% non-fat dry

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milk and incubated with the primary antibody anti-flotillin-1 (dilution 1:1000) for 16 h at 4 °C.

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Specific MV marker flotillin-140,41 was detected with mouse monoclonal anti-Flotilin-1 (dilution

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1:1000). After 3 washes with PBS-Tween, filters were incubated with peroxidase-conjugated

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anti-mouse secondary antibody (dilution 1:1000). Optical density of immunolabeled ECL-

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exposed protein bands was measured with UVI-1D software.

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For the Atomic Force Microscopy (AFM) characterization, MVs were diluted 1:10 in PBS

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buffer solution and processed as described in Junker et al. 2009.65 Briefly, a 15 µL drop of

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sample solution was placed and let to adsorb (15 min) onto a freshly peeled mica substrate

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thereafter rinsed with PBS. In order to reduce vesicle collapsing during AFM analysis, vesicles

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were fixed with 1% formaldehyde for 1 h (RT). MVs were then washed with PBS and dried

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under a gentle stream of N. AFM was used in semi-contact mode at RT in air using a

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commercial instrument (Solver Pro, NT-MDT, RU). Silicon tips (NSC36/CR-AU, MikroMash,

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US) with a typical force constant of 0.6 nN/nm and a resonance frequency of about 65 kHz

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were employed. Topographic height and phase images were recorded at 512×512 pixels at a

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scan rate of 0.5 Hz. Image processing was performed using Gwyddion freeware AFM analysis

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software, version 2.40.66 For statistical analysis, 107 individual MVs were imaged in 7

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different fields and measured. In particular, width and height of each vesicle were evaluated

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from cross line profiles and results were statistically analyzed using Igor Pro software

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(Wavemetrics. US).

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ASSOCIATED CONTENT

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Supporting Information: Supporting Results, Figure S1- S8 and Tables S1-S2.

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AUTHOR INFORMATION

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Corresponding Author

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* Laura Ballerini International School for Advanced Studies (SISSA) via Bonomea 265 I-34136

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Trieste phone +39 0403787779, LB [email protected]

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Author Contributions

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R.R. and A.F. performed cell biology, electrophysiology and immunofluorescence experiments

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and analysis; R.R. and F.P.U.S. design and performed imaging and real-time imaging

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experiments and analysis; N.L. and K.K. contributed to the synthesis and characterization of

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thin graphene oxide (l-GO and s-GO) of biological-grade; V.L. and E.V. contributed to the

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synthesis and characterization of pristine graphene (GR); M.M. performed glial cell

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experiments, immunofluorescence and western blot; D.S., I.R. and L.C. designed and

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performed the AFM experiments; L.B. and M.P. conceived the study; L.B. conceived the

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experimental design and contributed to the analysis of data; L.B. wrote the manuscript. All

22

authors have given approval to the final version of the manuscript.

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Funding Sources

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We acknowledge financial support from the EU FP7-ICT-2013-FET-F GRAPHENE Flagship

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project (no. 604391), from the NEUROSCAFFOLDS-FP7-NMP-604263 and PRIN-MIUR n.

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2012MYESZW.

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Notes

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The authors declare no competing financial interest.

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ACKNOWLEDGMENTS

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We are especially grateful to Micaela Grandolfo, Jessica Franzot and Beatrice Pastore for supervising

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the synaptic immune staining and quantification, the glial cell culturing and western blot experiments.

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IOM-TASC national laboratory (Trieste) is also gratefully acknowledged for AFM assistance. N.L.

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acknowledges Leon Newman for assistance with the TEM and Raman instrumentation. The authors

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would like to acknowledge the staff in the Faculty of Life Sciences EM Facility and the Wellcome Trust

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for equipment grant support to the EM Facility. The University of Manchester Bioimaging Facility

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microscopes used in this study were purchased with grants from the BBSRC, Wellcome Trust and the

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University of Manchester Strategic Fund X-ray photoelectron spectra were performed at the National

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EPSRC XPS User's Service (NEXUS) at Newcastle University, an EPSRC Mid-Range Facility. The

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Antolin Group is also acknowledged for the provision of the commercial material. We acknowledge

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financial support from the EU FP7-ICT-2013-FET-F GRAPHENE Flagship project (no. 604391), from

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the NEUROSCAFFOLDS-FP7-NMP-604263 and PRIN-MIUR n. 2012MYESZW.

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Figure 1. Characterization of small graphene oxide (s-GO) of biological-grade; graphene oxide exposure at high concentration influences synaptic function. In (a-f) physicochemical characterization of s-GO: (a) TEM micrograph (scale bar 1 µm). (b) AFM height image (scale bar 1 µm), (c) lateral dimension distribution and (d) thickness distribution analysis. (e) Normalized Raman spectrum. (f) TGA analysis. In (g) graphene oxide exposure at high concentration influences synaptic function. Spontaneous synaptic activity recorded from hippocampal cultures in control, melamine, s-GO and GR-treated cultures at 1 µg/mL (top traces) and 10 µg/mL (bottom traces) grown for 8 to 10 DIV. PSCs were detected at -56 mV holding potential. Bottom plots represent pooled data and summarize average PSCs amplitude and frequency: note the reduction in sGO-treatment (10 µg/mL, final concentration) of PSCs frequency (*** = P < 0.001 Student’s test, data are mean ± SEM). 262x371mm (300 x 300 DPI)

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Figure 2. s-GO exposure at high concentration impaired network activity without changing network size. In (a) immunofluorescence images are shown to visualize neurons and glial cells in the 4 different conditions (anti β-tubulin III, in red, left panels; anti-GFAP, in green, right panels, in all nuclei are visualized by DAPI in blue) (samples are for the 10 µg/mL protocol; scale bar 50 µm). The plots summarize neuronal (left) and glial (right) densities in all conditions. In (b) repetitive Ca2+-oscillations spontaneously (left panel) or bicuculline-induced (right panel) recorded in hippocampal cultures at 8 to 10 DIV (from each field sample recordings of 2 cells were selected). Histograms summarize the percentage of spontaneous active cells (middle) and the average values of the inter-event-interval (IEI; right) in standard saline (Krebs) and in the presence of bicuculline (*** = P < 0.001 Student’s-t-test, data are mean ± SEM). 262x371mm (300 x 300 DPI)

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Figure 3. s-GO exposure at high concentration impaired excitatory synapses. In (a) sample tracings of mPSCs recorded in control and s-GO-treated cultures (left panel). Right panel: plots reporting mPSC amplitude and frequency values. s-GO-treatment significantly decreased the frequency of mPSCs (*** = P < 0.001 Student’s-t-test). In (b) confocal reconstruction of control and s-GO treated neurons immunolabeled for the vesicular glutamate transporter 1 (VGLUT1; green) and counterstained for cytoskeletal component βtubulin III (red; nuclei are visualized by DAPI in blue; scale bar 10 µm). The plot shows the significant decrease of VGLUT1-positive puncta in s-GO-treated cultures (*** = P < 0.001 Student’s-t-test). In (c) top, fluorescence images following staining with FM1-43, control and s-GO-treated. Scale bar 50 µm. The areas in the boxes are higher magnifications to highlight the difference in vesicular staining between the two conditions (scale bar 100 µm). The plot (top right) reproduces the representative (control and s-GO) traces of FM1-43 de-staining (please note that each trace has been normalized to the maximum fluorescence detected). Bottom: the left plot summarizes the initial raw fluorescent intensities of hippocampal terminals from control and s-GO-treated cultures (** = P < 0.01 Mann-Whitney test); the right plot summarizes the

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decay time constant τ of FM1-43 de-staining in the two conditions (*** = P < 0.001, Mann-Whitney test). 262x371mm (300 x 300 DPI)

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Figure 4. s-GO exposure and microvesicles release in glial cells. In (a) immunolabeling of primary rat astrocytes (3 weeks) in control and s-GO treated cells (10 µg/mL 6-8 days). Both cultures were immunestained for GFAP (green) and nuclei visualized by DAPI (blue; scale bar: 100 µm). No statistical significance was found between the two conditions (top right). In (b) AFM image of fixed MVs where the differences in color are representative of height differences (brighter means higher). A representative height profile crossing 3 MVs is reported. The scatter plot (right) shows MVs width versus height distribution and is fitted with a regression line represented by the equation y = 0.046x + 0.218. A frequency histogram, built upon experimental measurements of both width and height, was plotted over each axis of the scatter graph, and fitted with Gaussian distributions. The frequency histograms revealed the highest number of occurrences to be about 490 nm and 24 nm for width and height, respectively. In (c) Western blotting of the pellets (bottom row) and cell lysates (top row) for the MVs marker flotillin-1. Pellets were obtained from the medium of glial cultures treated or un-treated with s-GO, under 2 different conditions: stimulated and not stimulated (Krebs) by 100 µM BzATP. Note the marked increase of the band for flotilin-1 in s-GO treated

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cells. In (d) plots summarizing the decreased density of hippocampal cells when treated with L-GO (~ 10 µm lateral size; 10 µg/mL final concentration). 262x371mm (300 x 300 DPI)

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TOC file 76x40mm (300 x 300 DPI)

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